A series of new germanates was prepared and their structures were characterized with X-ray diffraction (XRD). We employed solid-state synthesis, flux growth, and crystallization from melts to obtain crystals of the new materials. The crystals were studied by means of single crystal XRD, providing the information on the structure and composition of the new materials. Germanates suitable to accommodate Mn4+ – a well-known activator ion for the preparation of the rare-earth-free red phosphors – were of a particular interest. The Ge4+ substitution for Mn4+ is possible if the crystal structure features octahedrally coordinated germanium atoms, and we indeed were able to prepare such germanates.
The crystal structures of the following phases were characterized: Mg3Ge1-O4(1-)F2(1+2) ( ≈ 0.1), Mg14Ge4O20F4, Mg2Pb2Ge2O7F2, Sr3GeO4Cl2, Ba3GeO4Br2, Sr6Ge2O7Cl6, Ba5GeO4Br6, Na2BaGe8O18, Rb2BaGe8O18, Na0.36Sr0.82Ge4O9, Na2SrGe6O14, and K2SrGe8O18. Two phases, Mg3Ge1-O4(1-)F2(1+2) and Na0.36Sr0.82Ge4O9 demonstrate deficiency on certain crystallographic sites. We analyzed the connectivity of the GeO4 and GeO6 units in the new and reported tetra- and octagermanates. Despite the similar stoichiometry, the connectivity of GeOn polyhedra is different in RI2Ge4O9, RIIGe4O9 and RIRIIGe8O18 germanates (RI = alkali, RII = alkaline earth metal).
The Ge4+ substitution for Mn4+ was successfully done for the Na2BaGe8O18, Rb2BaGe8O18, Na2SrGe6O14, and K2SrGe8O18 phases yielding new red phosphors. Based on the powder XRD data, the optimal synthetic strategies were developed yielding high purity (≈ 99 wt. %) samples. The photoluminescent excitation and emission spectra were collected for the new phosphors. Strong absorption of the UV light and emission in the far-red region of the visible spectra were confirmed, which is in a good agreement with the literature. The Mn4+ doping level was optimized to achieve the highest luminescence in the studied phases. Temperature-dependent luminescence spectra were collected for the Na2SrGe6O14 : Mn4+ and K2SrGe8O18: Mn4+, and the K2SrGe8O18: Mn4+ showed the highest resistance to temperature quenching. / Thesis / Doctor of Philosophy (PhD)
Identifer | oai:union.ndltd.org:mcmaster.ca/oai:macsphere.mcmaster.ca:11375/28233 |
Date | January 2022 |
Creators | Novikov, Sergei |
Contributors | Mozharivskyj, Yurij, Chemistry |
Source Sets | McMaster University |
Language | English |
Detected Language | English |
Type | Thesis |
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